JP2019013685A - Bedside monitor and biological information monitoring system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a bedside monitor and a biological information monitoring system capable of enhancing cooperation between bedside monitors at the time of patient transfer and reducing the burden on medical staff at the time of patient movement. A bedside monitor 11A to 11X, 12A to 12X, and 13A to 13X hold an alarm set value and a measurement parameter set value of their own device in the transport monitor 20 when the transport monitor 20 is connected. It can be changed based on the set alarm setting value and measurement parameter setting value. As a result, the medical staff does not have to newly input the alarm set value and the measurement parameter set value. [Selection diagram] Fig. 2

Description

  The present invention relates to a bedside monitor and a biological information monitoring system.

  In a medical field such as a hospital, it is necessary to collect, analyze, and display biometric information (for example, electrocardiogram, blood pressure, number of breaths, and pulse) of each patient as needed. In addition, since the patient is transferred to a hospital room, examination room, operating room, etc., it is necessary to collect the patient's biological information together with the transfer of the patient. Small medical portable monitor systems (see, for example, Patent Documents 1 and 2) are widely used.

  As this type of system, there is a system in which a portable transport monitor can be connected to a stationary bedside monitor (specifically, dockable and removable). This kind of bedside monitor can also be called a host monitor for a transport monitor.

  The transport monitor has a terminal unit to which an electrocardiogram measurement electrode and the like are connected, a small display, a data storage device, a battery, and the like, and acquires and displays and records biological information without interruption even while the patient is transported. be able to. The biological information recorded on the transport monitor during the transfer of the patient is transferred to the bedside monitor when the transport monitor is docked on the bedside monitor. The biological information transferred to the bedside monitor is also sent to the central monitor connected to the bedside monitor.

  By using such a system having a transport monitor, it is possible to easily acquire the biological information of the patient being transferred. In addition, since the transport monitor is docked to the bedside monitor, the biometric information acquisition electrode attached to the patient can be connected without reconnection between the bedside monitor and the transport monitor. Measurement of biological information can be continued by simply plugging / unplugging the port monitor into / from the bedside monitor.

Japanese National Patent Publication No. 8-504345 Japanese National Patent Publication No. 8-504531

  However, in the conventional biological information monitoring system, sufficient consideration has not been given to cooperation between the bedside monitors when the patient is transferred.

  The present invention has been made in consideration of the above points, and enhances the cooperation between bedside monitors at the time of patient transfer, and can reduce the burden on medical personnel at the time of patient movement, and biological information Provide a monitoring system.

One aspect of the bedside monitor of the present invention is:
A bedside monitor for use in a biological information monitoring system having a bedside monitor and a portable transport monitor connectable to the bedside monitor,
A connection to which the transport monitor is connected;
When the transport monitor is connected to the connection unit, the alarm setting value and / or measurement parameter setting value of the own device is changed based on the alarm setting value and / or measurement parameter setting value held in the transport monitor. Possible controls,
It comprises.

One aspect of the biological information monitoring system of the present invention is:
A biological information monitoring system comprising: a plurality of bedside monitors connected to each other via a network; and a transportable transport monitor connectable to the plurality of bedside monitors,
At least one bedside monitor among the plurality of bedside monitors is:
A connection to which the transport monitor is connected;
When the transport monitor is connected to the connection unit, the alarm setting value and / or measurement parameter setting value of its own device is displayed as the alarm of the bedside monitor to which the transport monitor was previously connected via the network. A control unit that can be changed based on set values and / or measurement parameter values;
It comprises.

  According to the present invention, when the patient is transferred, the previous alarm setting value and / or parameter setting value is taken over even if the medical staff does not newly input the alarm setting value and / or measurement parameter value. It is possible to realize a bedside monitor and a biological information monitoring system that can reduce the burden on medical staff when moving patients.

It is a figure which shows the mode of the docking (connection) of the bedside monitor and transport monitor which concerns on embodiment, FIG. 1A is a figure which shows a mode that a transport monitor is removed from a bedside monitor, FIG. 1B is a figure with a patient. The figure which shows a mode that a port monitor is moved, FIG. 1C is a figure which shows a mode that a transport monitor is docked to a bedside monitor The figure which shows schematic structure of the hospital system to which the bedside monitor and transport monitor of embodiment are connected The block diagram which shows the structure of the bedside monitor of embodiment Diagram showing the screen displayed on the touch panel when the transport monitor is removed from the bedside monitor The figure which shows the patient selection screen displayed on the touch panel when the transport monitor is connected to the bedside monitor Diagram used to explain the movement of the transport monitor and the accompanying changes in alarm settings and measurement parameter settings Diagram used to explain the movement of the transport monitor and the accompanying changes in alarm settings and measurement parameter settings Diagram used to explain the movement of the transport monitor and the accompanying changes in alarm settings and measurement parameter settings Figure showing the change inquiry screen Diagram showing an example of transport monitor movement

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

<1> Overall Configuration First, the overall configuration and the premise configuration of the embodiment will be described.

  FIG. 1 is a diagram showing how the bedside monitors 11 and 12 and the transport monitor 20 are docked (connected). Although not shown here, the transport monitor 20 is connected to a biological information detection unit for acquiring patient biological information such as an electrocardiogram measurement electrode.

  When a patient is transferred from a place where the bedside monitor 11 is placed to a place where the bedside monitor 12 is placed, a medical worker such as a doctor or a nurse removes the transport monitor 20 from the bedside monitor 11. (FIG. 1A) After the transport monitor is moved together with the patient (FIG. 1B), the transport monitor 20 is docked on the bedside monitor 12 (FIG. 1C). By doing so, the patient's biological information can be acquired by the transport monitor 20 even during transfer of the patient.

  Here, the bottom and side surfaces of the transport monitor 20 and the surfaces of the bedside monitors 11 and 12 corresponding thereto are provided with connector portions that are electrically connected to each other when docked. The port monitor 20 and the bedside monitors 11 and 12 can transmit and receive information such as biological information and setting information to each other via the connector unit.

  The characteristics of each device when the bedside monitors 11 and 12 and the transport monitor 20 are compared with each other are as follows.

Bedside monitor:
・ It is supposed to be installed on the bedside and is heavier than the transport monitor.
-There are more measurement parameters for biometric information than can be displayed on the transport monitor.
-The number of external devices that can be connected is larger than the transport monitor.
-The display is larger than the transport monitor, and an extended display can be connected.
・ It is assumed that the central monitor is connected to the network.

Transport monitor:
・ It is supposed to be carried and is smaller and lighter than the bedside monitor.
-The number of biological information measurement parameters that can be displayed is smaller than that of the bedside monitor.
-The number of external devices that can be connected is less than the bedside monitor.
-The display is smaller than the bedside monitor.
-It has a memory that can record patient's biological information while moving. This memory has a capacity capable of recording biological information for 10 days, for example.

  Note that the bedside monitor and the transport monitor do not necessarily have all of the above features, but at least the transport monitor is configured to be smaller and lighter than the bedside monitor and can be carried.

  FIG. 2 is a diagram showing a schematic configuration of an in-hospital system (hereinafter referred to as “in-hospital system”) 10 to which the bedside monitor and the transport monitor of the present embodiment are connected. In the hospital system 10, one or more bedside monitors 11A to 11X are installed in an operating room, one or more bedside monitors 12A to 12X are installed in an ICU (Intensive Care Unit), and one or more bedside monitors are installed in a ward. Bedside monitors 13A to 13X are installed. Note that the “ward” described in this specification is a so-called “general ward” excluding a special treatment room such as an operating room or an ICU.

  The bedside monitors 11A to 11X in the operating room are connected to the central monitor 31, the bedside monitors 12A to 12X in the ICU are connected to the central monitor 32, and the bedside monitors 13A to 13X in the ward are connected to the central monitor 33. It is connected.

  Further, the central monitors 31, 32, 33 are connected to the server device 40. Thereby, the biological information acquired by the bedside monitors 11A to 11X is collected and displayed and recorded on the central monitor 31, and the biological information acquired by the bedside monitors 12A to 12X is collected to the central monitor 32. Display and recording are performed, and the biological information acquired by the bedside monitors 13A to 13X is collected on the central monitor 33 and displayed or recorded. In addition, the biological information acquired by the central monitors 31, 32, and 33 is collected and recorded in the server device 40. The server device 40, for example, records the biological information in response to requests from the central monitors 31, 32, 33 and bedside monitors 11A-11X, 12A-12X, 13A-13X, and the central monitors 31, 32, 33 and bedside monitors. 11A to 11X, 12A to 12X, and 13A to 13X.

  The transport monitor 20 can be docked (connected) to each of the bedside monitors 11A to 11X, 12A to 12X, and 13A to 13X, moves with the patient, and the bedside monitors 11A to 11X to which the patient has been transferred. , 12A to 12X and 13A to 13X.

  Although FIG. 2 shows the hospital system 10, the transport monitor 20 can be docked (connected) to, for example, a bedside monitor provided in an ambulance.

<2> Configuration of Bedside Monitor FIG. 3 is a block diagram showing the configuration of the bedside monitor 100 of the present embodiment. The bedside monitor 100 is used as the bedside monitors 11A to 11X, 12A to 12X, and 13A to 13X in FIGS.

  The bedside monitor 100 has connector portions 101, 102, and 103.

The connector unit 101 is a connector for connecting a biological information detection unit attached to a patient to the bedside monitor 100. The connector portion 101, SpO ₂ sensor for detecting electrocardiogram measurement electrode 201 for detecting an electrocardiogram, blood pressure cuff 202 for detecting the blood pressure, body temperature sensor 203, SpO ₂ for detecting the temperature 204, and a biological information detection unit such as a cardiac output sensor 205 for detecting the cardiac output are connected.

  The transport monitor 20 is connected to the connector unit 102. The central monitor 30 is connected to the connector unit 103.

The measurement processing unit 104 executes a predetermined measurement process to thereby detect a biological information detection unit (an electrocardiographic electrode 201, a blood pressure measurement cuff 202, a body temperature sensor 203, an SpO ₂ sensor 204, and a heart rate) connected to the connector unit 101. The patient's biological information is measured using the output sensor 205). In addition, since the conventionally well-known thing is applicable about the measuring method of various biological information using the said biological information detection part, the detailed description is abbreviate | omitted here. The biological information obtained by the measurement processing unit 104 is stored in the storage unit 105 and displayed on the touch panel 109.

  On the other hand, the biological information acquired by the transport monitor 20 is stored in the storage unit 105 via the connector unit 102 and the transmission / reception processing unit 106. Incidentally, the biological information acquired by the transport monitor 20 during the movement of the transport monitor 20 is temporarily stored in a storage unit (not shown) of the transport monitor, and when connected to the bedside monitor 100, the connector unit. The data is transferred and stored in the storage unit 105 of the bedside monitor 100 via the communication unit 102 and the transmission / reception processing unit 106.

  The biological information stored in the storage unit 105 is sent to the central monitor 30 via the transmission / reception processing unit 106 and the connector unit 103. Thereby, the central monitor 30 can display and record the biological information acquired by the bedside monitor 100 and the transport monitor 20.

  The control unit 110 controls the measurement processing unit 104, the transmission / reception processing unit 106, the display control unit 107, and the alarm indicator 108.

  The touch panel 109 is controlled by the display control unit 107 and displays biological information in the form of measurement values or waveforms. The touch panel 109 not only has a display function for displaying biological information, but also has a function as an operation input unit that receives an input operation by an operator. Specifically, information indicating the touch operation of the user on the touch panel 109 is sent from the touch panel 109 to the control unit 110, and the control unit 110 changes the display on the touch panel 109 or the mode of the bedside monitor 100 according to the touch operation. Perform various registration processes.

  The alarm indicator 108 is provided on the upper part of the casing of the bedside monitor 100 and emits red light, for example, when the control unit 110 determines that an abnormality has occurred in the biological information.

  The bedside monitor 100 includes a connection detection unit 111 and an ID identification unit 112. The connection detection unit 111 detects whether the transport monitor 20 is connected to the connector unit 102 and sends the detection result to the control unit 110. The ID identification unit 112 inputs the patient ID set in the transport monitor 20 connected to the connector unit 102 via the connector unit 102, and the patient ID of the transport monitor 20 to which this patient ID was previously connected. And the identification result is sent to the control unit 110.

  When the transport monitor 20 is removed from the bedside monitor 100, this is detected by the connection detection unit 111, and the screen shown in FIG. 4 is displayed on the touch panel 109. When the “monitor interruption” button is touched by the user (healthcare professional), the bedside monitor 100 enters a monitoring interruption mode, and the monitoring of biological information is interrupted. On the other hand, when the “Leave” button is touched by the user, the bedside monitor 100 performs the exit process.

  When the transport monitor 20 is connected to the bedside monitor 100, this is detected by the connection detection unit 111, and the patient selection screen shown in FIG. 5 is displayed on the touch panel 109. In this screen, the user uses the patient information associated with the patient ID set in the transport monitor 20 and the patient associated with the patient ID set in the apparatus (bedside monitor 100). Either a mode using information or a mode in which patient information is newly input and monitoring is started can be selected.

<3> Change of Alarm Set Value and Measurement Parameter Set Value According to Embodiment Next, change of the alarm set value and the measurement parameter set value according to the present embodiment will be described.

  6 to 8 are diagrams illustrating an example of movement of the transport monitor 20 and change of the alarm setting value and the measurement parameter setting value associated therewith.

  First, as shown in FIG. 6, the transport monitor 20 is docked to the bedside monitor 12A of the ICU, and the biological information is acquired in this state. In this case, the bedside monitor 12A operates with the alarm setting value and the measurement parameter setting value that are currently set in the device itself (that is, the bedside monitor 12A).

  Incidentally, the alarm set value is a threshold value that is a criterion for alarm output. The measurement parameter setting value is a setting value of a measurement parameter when measuring each biological information. For example, when the impedance respiration is easier to measure by the patient than the II induction by the patient, the measurement parameter for the respiration detection induction is set to the I induction. Also, for example, when the ECG detection sensitivity is changed for each lead, the measurement parameter setting value is used, and the NIBP measurement interval is also defined by the measurement parameter setting value.

  The transport monitor of the present embodiment receives the alarm setting value and measurement parameter setting value of the docked bedside monitor 12A from the bedside monitor 12A, and stores them in the storage unit 105 (FIG. 3) in a file format. The alarm setting value and measurement parameter setting value of the bedside monitor 12A include the alarm setting value and measurement parameter setting value of the transport monitor 20. Usually, the alarm operation and the biological information measurement operation of the transport monitor are simpler than the alarm operation and the biological information measurement operation of the bedside monitor. This is because part of the alarm setting values and measurement parameter setting values of the side monitor can be used.

  Next, as shown in FIG. 7, the transport monitor 20 is removed from the bedside monitor 12A, and the moving biological information is acquired while moving with the patient. At this time, the transport monitor 20 operates with the alarm setting value and the measurement parameter setting value of the transport monitor 20.

  Next, as shown in FIG. 8, the transport monitor 20 is docked to the bedside monitor 13A of the ward. The bedside monitor 13A receives the alarm setting value and measurement parameter setting value of the bedside monitor 12A from the transport monitor 20, and operates with the alarm setting value and measurement parameter setting value of the bedside monitor 12A.

  In practice, when the bedside monitor 13A detects that the transport monitor 20 is connected by the connection detection unit 111, the control unit 110 accesses the storage unit of the transport monitor 20 via the transmission / reception processing unit 106, Based on the alarm setting value and measurement parameter setting value of the bedside monitor 12A stored in the storage unit, the alarm setting value and measurement parameter setting value of the own apparatus are changed.

  However, when the transport monitor 20 is docked, the bedside monitor 13A holds the alarm setting value and the measurement parameter setting value of its own device in the transport monitor 20 on the touch panel 109 as shown in FIG. An inquiry screen as to whether or not to change based on the set alarm setting value and measurement parameter setting value is displayed. Then, when the user operates the “change setting” button after operating the “yes” button, the alarm setting value and measurement parameter setting value of the own device are changed to the alarm setting value held in the transport monitor 20 and Change based on measurement parameter settings. On the other hand, when the user operates the “setting change” button after operating the “no” button, the alarm setting value and the measurement parameter setting value of the own device are held in the transport monitor 20. Instead of changing to the alarm setting value and the measurement parameter setting value, for example, biological information is measured using the alarm setting value and the measurement parameter setting value that are already set in the device itself.

  Thereby, a medical worker who operates the bedside monitor 13A wants to perform measurement of biological information inheriting the alarm setting value and the measurement parameter setting value in the bedside monitor 12A to which the transport monitor was previously connected. Thus, it is not necessary to newly input alarm setting values and measurement parameter setting values similar to those of the bedside monitor 12A. As a result, the burden on the medical staff at the time of patient transfer can be reduced.

<4> Effects of the Embodiment As described above, according to the present embodiment, the bedside monitor 100 is configured such that when the transport monitor 20 is connected, the alarm setting value and the measurement parameter setting value of the device itself. Can be changed based on the alarm setting value and the measurement parameter setting value held in the transport monitor 20. Thereby, the bedside monitor 100 which can raise the cooperation between the bedside monitors at the time of patient movement, and can reduce the burden of the medical staff at the time of patient movement is realizable.

<5> Other Embodiments The above-described embodiments are merely examples of implementation in carrying out the present invention, and the technical scope of the present invention should not be construed as being limited thereto. It will not be. That is, the present invention can be implemented in various forms without departing from the gist or main features thereof.

  <5-1> In the above-described embodiment, the alarm setting value and the measurement parameter setting value of the bedside monitor 12A to which the transport monitor 20 was previously connected are stored in the transport monitor 20, and this is connected next. The transport monitor 20 does not store the alarm setting value and measurement parameter setting value of the bedside monitor 12A, but the alarm setting of the own device (that is, the transport monitor 20). The value and the measurement parameter setting value may be passed to the bedside monitor 13A. In this way, the bedside monitor 13A can operate based on the alarm setting value and the measurement parameter setting value of the transport monitor 20.

  However, usually, the alarm setting value and measurement parameter setting value of the transport monitor 20 are often different in the number of measurement parameters and setting accuracy from the alarm setting value and measurement parameter setting value for the bedside monitor. That is, the bedside monitor uses more values as the alarm setting value and measurement parameter setting value than the transport monitor.

  Considering this, the bedside monitor 13A receives the alarm setting value and measurement parameter setting value of the transport monitor 20 from the transport monitor 20 when the transport monitor 20 is connected, and also via the network. It is preferable that the alarm setting value and the measurement parameter setting value of the bedside monitor 12A to which the transport monitor 20 was previously connected can be acquired. In this way, the alarm setting value and measurement parameter setting value that are insufficient in the alarm setting value and measurement parameter setting value of the transport monitor 20 are transferred to the bedside where the transport monitor 20 was previously connected via the network. It can be received from the monitor 12A or the central monitor 32.

  Incidentally, since the patient ID is transmitted to the bedside monitors 12A and 13A via the transport monitor 20, the central monitors 32 and 33 of the bedside monitors 12A and 13A are connected to the bedside monitors 12A and 13A. The patient ID is grasped. Therefore, the alarm setting value and the measurement parameter setting value of the bedside monitor 12A of the corresponding patient ID are sent via the central monitor 33, 32 to the bedside monitor 13A to which the transport monitor 20 is newly connected via the network. Can do.

  This will be specifically described. The bedside monitor 13A to which the transport monitor 20 is connected inquires of the central monitor 33 about the alarm setting value and measurement parameter setting value of patient ID = A. Then, the central monitor 33 requests the latest alarm setting value and measurement parameter setting value of the patient ID = A from the server device 40. The server device 40 obtains the alarm setting value and measurement parameter setting value of the latest time of the patient ID = A from the central monitor 32 and passes them to the central monitor 33. The central monitor 33 passes this alarm setting value and measurement parameter setting value to the bedside monitor 13A. As a result, the alarm setting value and measurement parameter setting value of the patient ID = A of the bedside monitor 13A and the central monitor 33 are changed to the same values as those of the bedside monitor 12A to which the transport monitor 20 was previously connected.

  The bedside monitor 13A to which the transport monitor 20 is connected does not receive the alarm setting value and the measurement parameter setting value from the transport monitor 20, and acquires all the alarm setting values and the measurement parameter setting values via the network. You may do it.

  <5-2> In the above embodiment, when the transport monitor 20 is connected, the bedside monitor 13A displays an inquiry screen as shown in FIG. Although it is possible to select whether to change the value, the configuration for realizing whether to change the value is not limited to the configuration that displays the inquiry screen.

  For example, a configuration may be adopted in which a room that is allowed to be changed and a room that is not allowed to be changed are set in advance. This will be described. As shown in FIG. 10, it is assumed that the transport monitor 20 is connected in order to the bedside monitor in the ward → the bedside monitor in the operating room → the bedside monitor in the ICU → the bedside monitor in the ward. Here, generally, the alarm setting value and measurement parameter setting value of the bedside monitor of the ward are greatly different from the alarm setting value and measurement parameter setting value of the bedside monitor of the operating room or ICU. Therefore, when the transport monitor 20 is connected to the bedside monitor of the ward, if the bedside monitor to which the transport monitor was connected immediately before is the one in the ICU or operating room, the change is not permitted, and the ward If it is, you should set it to allow changes.

  In the case where the alarm setting value and the measurement parameter setting value are received via the network, the bedside monitor to which the transport monitor 20 is connected has an alarm setting value corresponding to the patient ID identified by the patient ID identification unit. The bedside of the room corresponding to the ward, operating room, intensive care unit, emergency room, examination room, outpatient examination room, delivery room or ambulance where the measurement parameters are set and the bedside monitor is located It is preferable that the alarm setting value and the measurement parameter setting value of the bedside monitor to which the transport monitor 20 is newly connected among the monitors are acquired via the network. By the way, in the above-described embodiment, ward, operating room, intensive care unit, emergency room are given as examples where biometric information is acquired, that is, where a bedside monitor is installed. For example, it may be an examination room, an outpatient examination room, a delivery room, an ambulance, or the like.

  <5-3> In the above-described embodiment, the case where both the alarm setting value and the measurement parameter setting value are changed has been described. However, only one of them, for example, only the alarm setting value may be changed.

  <5-4> The transport monitor of the above-described embodiment can be replaced with a telemeter. That is, the transport monitor of the present invention means a movable biological information measuring device that can be connected to a bedside monitor.

  The present invention can be widely applied to bedside monitors capable of changing alarm setting values and measurement parameter setting values.

11, 11A to 11X, 12, 12A to 12X, 13A to 13X, 100 Bedside monitor 20 Transport monitor 30, 31, 32, 33 Central monitor 101, 102, 103 Connector section 110 Control section 111 Connection detection section 112 ID identification Part

Claims (10)

A bedside monitor for use in a biological information monitoring system having a bedside monitor and a portable transport monitor connectable to the bedside monitor,
A connection to which the transport monitor is connected;
When the transport monitor is connected to the connection unit, the alarm setting value and / or measurement parameter setting value of the own device is changed based on the alarm setting value and / or measurement parameter setting value held in the transport monitor. Possible controls,
Bedside monitor equipped with. When the transport monitor is connected to the connection unit, the alarm setting value and / or measurement parameter setting value of the own device is changed based on the alarm setting value and / or measurement parameter setting value held in the transport monitor. You can choose whether or not to
The bedside monitor according to claim 1. When the transport monitor is connected to the connection unit, the alarm setting value and / or measurement parameter setting value of the own device is changed based on the alarm setting value and / or measurement parameter setting value held in the transport monitor. A display unit for displaying an inquiry screen as to whether or not to perform,
The bedside monitor according to claim 2. The bedside monitor is network-connected to other bedside monitors,
When the transport monitor is connected to the connection unit, the alarm setting value and / or the measurement parameter setting value of the bedside monitor to which the transport monitor has been connected before among the other bedside monitors is transmitted to the network. Can be obtained through the
The bedside monitor according to any one of claims 1 to 3. A biological information monitoring system comprising: a plurality of bedside monitors connected to each other via a network; and a transportable transport monitor connectable to the plurality of bedside monitors,
At least one bedside monitor among the plurality of bedside monitors is:
A connection to which the transport monitor is connected;
When the transport monitor is connected to the connection unit, the alarm setting value and / or measurement parameter setting value of its own device is displayed as the alarm of the bedside monitor to which the transport monitor was previously connected via the network. A control unit that can be changed based on set values and / or measurement parameter values;
A biological information monitoring system comprising: The at least one bedside monitor is
When the transport monitor is connected to the connection unit, the alarm setting value and / or measurement parameter value of its own device, the alarm setting value and / or measurement parameter of the bedside monitor to which the transport monitor was previously connected It is possible to select whether to change based on the value,
The biological information monitoring system according to claim 5. The at least one bedside monitor is
When the transport monitor is connected to the connection unit, the alarm setting value and / or measurement parameter setting value of the own device can be changed via the transport monitor in addition to the network.
The biological information monitoring system according to claim 5 or 6. The at least one bedside monitor is
A patient ID identifying unit for identifying a patient ID set in the transport monitor when the transport monitor is connected to the connection unit;
An alarm setting value and / or a measurement parameter setting value corresponding to the patient ID identified by the patient ID identification unit is acquired via the network.
The biological information monitoring system according to any one of claims 5 to 7. The at least one bedside monitor is
Of the alarm setting value and / or measurement parameter setting value corresponding to the patient ID identified by the patient ID identification unit, the alarm setting value and / or measurement parameter setting value of the bedside monitor to which the transport monitor was connected immediately before Via the network,
The biological information monitoring system according to claim 8. The plurality of bedside monitors are provided in a ward, an operating room, an intensive care unit, an emergency room, an examination room, an outpatient examination room, a delivery room, and / or an ambulance,
The at least one bedside monitor is
A ward, an operating room, an intensive care unit, an emergency room, which are alarm setting values and / or measurement parameter setting values corresponding to the patient ID identified by the patient ID identifying unit, and where the own bedside monitor is arranged, Alarm setting value and / or measurement parameter setting value of the bedside monitor to which the transport monitor is newly connected in time among the bedside monitors of the examination room, outpatient examination room, delivery room or ambulance room, Obtain via the network,
The biological information monitoring system according to claim 8.

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